The crystal structure of isopenicillin N synthase with δ-(l-α-aminoadipoyl)-l-cysteinyl-d-methionine reveals thioether coordination to iron

Isopenicillin N synthase (IPNS) catalyses cyclization of δ-(l-α-aminoadipoyl)-l-cysteinyl-d-valine (ACV) to isopenicillin N (IPN), the central step in penicillin biosynthesis. Previous studies have shown that IPNS turns over a wide range of substrate analogues in which the valine residue of its natural substrate is replaced with other amino acids. IPNS accepts and oxidizes numerous substrates that bear hydrocarbon sidechains in this position, however the enzyme is less tolerant of analogues presenting polar functionality in place of the valinyl isopropyl group. We report a new ACV analogue δ-(l-α-aminoadipoyl)-l-cysteinyl-d-methionine (ACM), which incorporates a thioether in place of the valinyl sidechain. ACM has been synthesized using solution phase methods and crystallized with IPNS. A crystal structure has been elucidated for the IPNS:Fe(II):ACM complex at 1.40 Å resolution. This structure reveals that ACM binds in the IPNS active site such that the sulfur atom of the methionine thioether binds to iron in the oxygen binding site at a distance of 2.57 Å. The sulfur of the cysteinyl thiolate sits 2.36 Å from the metal.     

Molecular characterization of a novel thermostable mannose-6-phosphate isomerase from Thermus thermophilus

Mannose-6-phosphate isomerase catalyzes the interconversion of mannose-6-phosphate and fructose-6-phosphate. The gene encoding a putative mannose-6-phosphate isomerase from Thermus thermophilus was cloned and expressed in Escherichia coli. The native enzyme was a 29 kDa monomer with activity maxima for mannose 6-phosphate at pH 7.0 and 80 °C in the presence of 0.5 mM Zn²⁺ that was present at one molecule per monomer. The half-lives of the enzyme at 65, 70, 75, 80, and 85 °C were 13, 6.5, 3.7, 1.8, and 0.2 h, respectively. The 15 putative active-site residues within 4.5 Å of the substrate mannose 6-phosphate in the homology model were individually replaced with other amino acids. The sequence alignments, activities, and kinetic analyses of the wild-type and mutant enzymes with amino acid changes at His50, Glu67, His122, and Glu132 as well as homology modeling suggested that these four residues are metal-binding residues and may be indirectly involved in catalysis. In the model, Arg11, Lys37, Gln48, Lys65 and Arg142 were located within 3 Å of the bound mannose 6-phosphate. Alanine substitutions of Gln48 as well as Arg142 resulted in increase of K_m and dramatic decrease of k_cat, and alanine substitutions of Arg11, Lys37, and Lys65 affected enzyme activity. These results suggest that these 5 residues are substrate-binding residues. Although Trp13 was located more than 3 Å from the substrate and may not interact directly with substrate or metal, the ring of Trp13 was essential for enzyme activity.     

Crystal Structure and Putative Mechanism of 3-Methylitaconate-Δ-isomerase from Eubacterium barkeri

3-Methylitaconate-Δ-isomerase (Mii) participates in the nicotinate fermentation pathway of the anaerobic soil bacterium Eubacterium barkeri (order Clostridiales) by catalyzing the reversible conversion of (R)-3-methylitaconate (2-methylene-3-methylsuccinate) to 2,3-dimethylmaleate. The enzyme is also able to catalyze the isomerization of itaconate (methylenesuccinate) to citraconate (methylmaleate) with ca 10-fold higher K_m but > 1000-fold lower k_cat. The gene mii from E. barkeri was cloned and expressed in Escherichia coli. The protein produced with a C-terminal Strep-tag exhibited the same specific activity as the wild-type enzyme. The crystal structure of Mii from E. barkeri has been solved at a resolution of 2.70 Å. The asymmetric unit of the P2₁2₁2₁ unit cell with parameters a = 53.1 Å, b = 142.3 Å, and c = 228.4 Å contains four molecules of Mii. The enzyme belongs to a group of isomerases with a common structural feature, the so-called diaminopimelate epimerase fold. The monomer of 380 amino acid residues has two topologically similar domains exhibiting an α/β-fold. The active site is situated in a cleft between these domains. The four Mii molecules are arranged as a tetramer with 222 symmetry for the N-terminal domains. The C-terminal domains have different relative positions with respect to the N-terminal domains resulting in a closed conformation for molecule A and two distinct open conformations for molecules B and D. The C-terminal domain of molecule C is disordered. The Mii active site contains the putative catalytic residues Lys62 and Cys96, for which mechanistic roles are proposed based on a docking experiment of the Mii substrate complex. The active sites of Mii and the closely related PrpF, most likely a methylaconitate Δ-isomerase, have been compared. The overall architecture including the active-site Lys62, Cys96, His300, and Ser17 (Mii numbering) is similar. This positioning of (R)-3-methylitaconate allows Cys96 (as thiolate) to deprotonate C-3 and (as thiol) to donate a proton to the methylene carbon atom of the resulting allylic carbanion. Interestingly, the active site of isopentenyl diphosphate isomerase type I also contains a cysteine that cooperates with glutamate rather than lysine. It has been proposed that the initial step in this enzyme is a protonation generating a tertiary carbocation intermediate.     

Structural investigation of porcine stomach mucin by X-ray fiber diffraction and homology modeling

The basic understanding of the three dimensional structure of mucin is essential to understand its physiological function. Technology has been developed to achieve orientated porcine stomach mucin molecules. X-ray fiber diffraction of partially orientated porcine stomach mucin molecules show d-spacing signals at 2.99, 4.06, 4.22, 4.7, 5.37 and 6.5 Å. The high intense d-spacing signal at 4.22 Å is attributed to the antiparallel β-sheet structure identified in the fraction of the homology modeled mucin molecule (amino acid residues 800–980) using Nidogen–Laminin complex structure as a template. The X-ray fiber diffraction signal at 6.5 Å reveals partial organization of oligosaccharides in porcine stomach mucin. This partial structure of mucin will be helpful in establishing a three dimensional structure for the whole mucin molecule.     

Crystal structure of Bifidobacterium Longum phosphoketolase; key enzyme for glucose metabolism in Bifidobacterium

The crystal structure of Bifidobacterium longum phosphoketolase, a thiamine diphosphate (TPP) dependent enzyme, has been determined at 2.2 Å resolution. The enzyme is a dimer with the active sites located at the interface between the two identical subunits with molecular mass of 92.5 kDa. The bound TPP is almost completely shielded from solvent except for the catalytically important C2-carbon of the thiazolium ring, which can be accessed by a substrate sugar through a narrow funnel-shaped channel. In silico docking studies of B. longum phosphoketolase with its substrate enable us to propose a model for substrate binding.

Structured summary

MINT-7985878: PKT (uniprotkb:Q6R2Q7) and PKT (uniprotkb:Q6R2Q7) bind (MI:0407) by X-ray crystallography (MI:0114)     

Tobacco Etch Virus Protease: Crystal Structure of the Active Enzyme and Its Inactive Mutant

Tobacco Etch Virus Protease (TEV protease) is widely used as a tool for separation of recombinant target proteins from their fusion partners. The crystal structures of two mutants of TEV protease, the active autolysis-resistant mutant TEV-S219D in complex with the proteolysis product, and the inactive mutant TEV-C151A in complex with a substrate, have been determined at 1.8 and 2.2 Å resolution, respectively. The active sites of both mutants, including their oxyanion holes, have identical structures. The C-terminal residues 217–221 of the enzyme are involved in formation of the binding pockets S ₃–S ₆. This indicates that the autolysis of the peptide bond Met218–Ser219 exerts a strong effect on the fine-tuning of the substrate in the enzyme active site, which results in a considerable decrease in the enzymatic activity.     

The Crystal Structure of the Complexes of Concanavalin A with 4′-Nitrophenyl-α-d-mannopyranoside and 4′-Nitrophenyl-α-d-glucopyranoside

Concanavalin A (Con A) is the best-known plant lectin and has importantin vitrobiological activities arising from its specific saccharide-binding ability. Its exact biological role still remains unknown. The complexes of Con A with 4′-nitro-phenyl-α-d-mannopyranoside (α-PNM) and 4′-nitrophenyl-α-d-glucopyranoside (α-PNG) have been crystallized in space group P2₁2₁2 with cell dimensionsa= 135.19 Å,b= 155.38 Å,c= 71.25 Å anda= 134.66 Å,b= 155.67 Å, andc= 71.42 Å, respectively. X-ray diffraction intensities to 2.75 Å for the α-PNM and to 3.0 Å resolution for the α-PNG complex have been collected. The structures of the complexes were solved by molecular replacement and refined by simulated annealing methods to crystallographic R-factor values of 0.185/0.186 and free-R-factor values of 0.260/0.274, respectively. In both structures, the asymmetric unit contains four molecules arranged as a tetramer, with approximate 222 symmetry. A saccharide molecule is bound in the sugar-binding site near the surface of each monomer. The nonsugar (aglycon) portion of the compounds used helps to identify the exact orientation of the saccharide in the sugar-binding pocket and is involved in major interactions between tetramers. The hydrogen bonding network in the region of the binding site has been analyzed, and only minor differences with the previously reported Con A–methyl-α-d-mannopyranoside complex structure have been observed. Structural differences that may contribute to the slight preference of the lectin for mannosides over glucosides are discussed. Calculations indicate a negative electrostatic surface potential for the saccharide binding site of Con A, which may be important for its biological activity. It is also shown in detail how a particular class of hydrophobic ligands interact with one of the three so-called characteristic hydrophobic sites of the lectins.     

Structural insights into unique substrate selectivity of Thermoplasma acidophilum D-aldohexose dehydrogenase

The d-aldohexose dehydrogenase from the thermoacidophilic archaea Thermoplasma acidophilum (AldT) belongs to the short-chain dehydrogenase/reductase (SDR) superfamily and catalyzes the oxidation of several monosaccharides with a preference for NAD⁺ rather than NADP⁺ as a cofactor. It has been found that AldT is a unique enzyme that exhibits the highest dehydrogenase activity against d-mannose. Here, we describe the crystal structures of AldT in ligand-free form, in complex with NADH, and in complex with the substrate d-mannose, at 2.1 Å, 1.65 Å, and 1.6 Å resolution, respectively. The AldT subunit forms a typical SDR fold with an unexpectedly long C-terminal tail and assembles into an intertwined tetramer. The d-mannose complex structure reveals that Glu84 interacts with the axial C2 hydroxyl group of the bound d-mannose. Structural comparison with Bacillus megaterium glucose dehydrogenase (BmGlcDH) suggests that the conformation of the glutamate side-chain is crucial for discrimination between d-mannose and its C2 epimer d-glucose, and the conformation of the glutamate side-chain depends on the spatial arrangement of nearby hydrophobic residues that do not directly interact with the substrate. Elucidation of the d-mannose recognition mechanism of AldT further provides structural insights into the unique substrate selectivity of AldT. Finally, we show that the extended C-terminal tail completely shuts the substrate-binding pocket of the neighboring subunit both in the presence and absence of substrate. The elaborate inter-subunit interactions between the C-terminal tail and the entrance of the substrate-binding pocket imply that the tail may play a pivotal role in the enzyme activity.     

The ultrastructure of organelles appearing in spermatids and nutritive cells of Cipangopaludina malleata

Summary The ultrastructure of organelles appearing in the early typical and atypical spermatids, and the nutritive cells of Cipangopaludina malleata has been examined by a Siemens' electron microscope Elmiskop I.Mitochondria appearing in the early typical spermatid have doughnut-like profiles in which the internal ridges appear as triple-layered membranes arranged radially and extending into the interior of the organelle without reaching the other side. Each membrane 40–60 Å in width, separated by a clear interspace 60–90 Å wide, is characterized by a porous structure 20–30 Å in diameter which suggests a filtration apparatus for enzymes.Walls of the flattened saccules consisting the Golgi apparatus are calculated 35–60 Å thick, in which an electron-lucent, porous structure about 30 Å wide has been revealed.The smooth-surfaced endoplasmic reticulum is bordered by a triple-layered membrane consisting of two opaque layers with a less opaque interspace 20–30 Å wide. The outer membrane ca. 15 Å wide presents a more linear appearance than the dotted arrangement of the inner membrane 20–25 Å thick.The plasma membrane is composed of a triple-layered structure where two dense lines 15 Å wide are separated by a layer 20–30 Å thick of less density.The electron micrographs for the present studies were taken with the Siemens electron microscope, model Elmiskop I, at the Anatomical Institute of Kiel University, Germany. The one of the authors, G. Yasuzumi is deeply grateful to Prof. Dr. W. Bargmann and Dr. A. Knoop for the privilege of using this instrument and other equipments in the Laboratory.     

Porphobilinogen deaminase and uroporphyrinogen III synthase: Structure,molecular biology,and mechanism

Porphobilinogen deaminase (hydroxymethylbilane synthase) and uroporphyrinogen III synthase (uroporphyrinogen III cosynthase) catalyze the transformation of four molecules of porphobilinogen, via the 1-hydroxymethylbilane, preuroporphyrinogen, into uroporphyrinogen III. A combination of studies involving protein chemistry, molecular biology, site-directed mutagenesis, and the use of chemically synthesized substrate analogs and inhibitors is helping to unravel the complex mechanisms by which the two enzymes function. The determination of the X-ray structure ofE. coli porphobilinogen deaminase at 1.76 Å resolution has provided the springboard for the design of further experiments to elucidate the precise mechanism for the assembly of both the dipyrromethane cofactor and the tetrapyrrole chain. The human deaminase structure has been modeled from theE. coli structure and has led to a molecular explanation for the disease acute intermittent porphyria. Molecular modeling has also been employed to simulate the spiro-mechanism of uroporphyrinogen III synthase.     

Structural analysis of a putative SAM-dependent methyltransferase,YtqB, from Bacillus subtilis

S-adenosyl-l-methionine (SAM)-dependent methyltransferases (MTases) methylate diverse biological molecules using a SAM cofactor. The ytqB gene of Bacillus subtilis encodes a putative MTase and its biological function has never been characterized. To reveal the structural features and the cofactor binding mode of YtqB, we have determined the crystal structures of YtqB alone and in complex with its cofactor, SAM, at 1.9 Å and 2.2 Å resolutions, respectively. YtqB folds into a β-sheet sandwiched by two α-helical layers, and assembles into a dimeric form. Each YtqB monomer contains one SAM binding site, which shapes SAM into a slightly curved conformation and exposes the reactive methyl group of SAM potentially to a substrate. Our comparative structural analysis of YtqB and its homologues indicates that YtqB is a SAM-dependent class I MTase, and provides insights into the substrate binding site of YtqB.     

Freeze fracture studies on the annelid septate junction

Summary Freeze-fractured preparations of septate junctions between epidermal cells of annelids (Lumbricus terrestris and Tubifex spec.) have been investigated. In Lumbricus the protoplasmic face (PF) of the plasma membrane is characterized by variously arranged rows of particles. Apically the rows take an undulating course and often are separated by wide distances. In the basal part of the junction the rows run closely together and more or less in parallel. The diameter of the particles measures 80–120 Å, the distance between two particles (centre to centre) is 150–250 Å. Additionally striking rows of large particles (long diameter 150–200 Å). Are to be observed mainly near the basal part of the junction. In Tubifex both faces of the plasma membrane could be studied in detail. The protoplasmic face (PF) contains rows of distinct individual particles (mean diameter 100–150 Å, centre to centre distance approx. 250 Å) whereas the particles of the extracellular face (EF, mean diameter 200–250 Å) usually form continuous strands in which the individual particles seem to fuse. The density of arrangement of the strands varies considerably. Additionally ladder-shaped membrane structures have been observed in plasma membranes of this species.     

Kinetic and structural characterization of DmpI from Helicobacter pylori and Archaeoglobus fulgidus, two 4-oxalocrotonate tautomerase family members

The tautomerase superfamily consists of structurally homologous proteins that are characterized by a β-α-β fold and a catalytic amino-terminal proline. 4-Oxalocrotonate tautomerase (4-OT) family members have been identified and categorized into five subfamilies on the basis of multiple sequence alignments and the conservation of key catalytic and structural residues. Representative members from two subfamilies have been cloned, expressed, purified, and subjected to kinetic and structural characterization. The crystal structure of DmpI from Helicobacter pylori (HpDmpI), a 4-OT homolog in subfamily 3, has been determined to high resolution (1.8 Å and 2.1 Å) in two different space groups. HpDmpI is a homohexamer with an active site cavity that includes Pro-1, but lacks the equivalent of Arg-11 and Arg-39 found in 4-OT. Instead, the side chain of Lys-36 replaces that of Arg-11 in a manner similar to that observed in the trimeric macrophage migration inhibitory factor (MIF), which is the title protein of another family in the superfamily. The electrostatic surface of the active site is also quite different and suggests that HpDmpI might prefer small, monoacid substrates. A kinetic analysis of the enzyme is consistent with the structural analysis, but a biological role for the enzyme remains elusive. The crystal structure of DmpI from Archaeoglobus fulgidus (AfDmpI), a 4-OT homolog in subfamily-4, has been determined to 2.4 Å resolution. AfDmpI is also a homohexamer, with a proposed active site cavity that includes Pro-1, but lacks any other residues that are readily identified as catalytic ones related to 4-OT activity. Indeed, the electrostatic potential of the active site differs significantly in that it is mostly neutral, in contrast to the usual electropositive features found in other 4-OT family members, suggesting that AfDmpI might accommodate hydrophobic substrates. A kinetic analysis has been carried out, but does not provide any clues about the type of reaction the enzyme might catalyze.     

Crystal Structure of Zebrafish Hatching Enzyme 1 from the Zebrafish Danio rerio

Fish hatching enzymes are zinc metalloproteases that digest the egg envelope (chorion) at the time of hatching. The crystal structure of zebrafish hatching enzyme 1 (ZHE1) has been solved at 1.10 Å resolution. ZHE1 is monomeric, is mitten shaped, and has a cleft at the center of the molecule. ZHE1 consists of three 3₁₀-helices, three α-helices, and two β-sheets. The central cleft represents the active site of the enzyme that is crucial for substrate recognition and catalysis. Alanine-scanning mutagenesis of the two substrate peptides has shown that AspP1′ contributes the most and that the residues at P4-P2′ also contribute to the recognition of the major substrate peptide by ZHE1, whereas GluP3′ and the hydrophobic residues at P4-P2, P2′, and P5′ contribute significantly to the recognition of the minor substrate peptide by ZHE1. Molecular models of these two substrate peptides bound to ZHE1 have been built based on the crystal structure of a transition-state analog inhibitor bound to astacin. In substrate-recognition models, the AspP1′ in the major substrate peptide forms a salt bridge with Arg182 of ZHE1, while the GluP3′ in the minor substrate peptide instead forms a salt bridge with Arg182. Thus, these two substrate peptides would be differently recognized by ZHE1. The shapes and electrostatic potentials of the substrate-binding clefts of ZHE1 and the structurally similar proteins astacin and bone morphogenetic protein 1 are significantly dissimilar due to different side chains, which would confer their distinctive substrate preferences.     

Some enzymatic properties of vacuolar alkaline phosphatase from yeast

Candida utilis alkaline phosphatase has been detected in vacuoles. Liberation of the vacuoles was carried out by protoplast disruption under isotonic conditions. The polybase DEAE-dextran was used to induce damage to the yeast plasmalemma. The vacuoles were purified by centrifugation on sorbitol-Ficoll gradients. Alkaline phosphatase from a purified fraction of vacuoles was characterized after gel filtration on Sephadex G-200. We have found 15 mU of enzyme activity per 10⁸ vacuoles. This enzyme activity elutes on Sephadex G-200 at a volume-to-void-volume ratio of 1.65. The approximate molecular weight is 1.35×10⁵. TheK _m value forp-nitrophenyl-phosphate is 2.5×10^–3 M. The pH for maximum activity is 8.9, and the enzyme is stable at pH values between 7.0 and 9.0. Rapid inactivation occurs at temperatures above 45°C. The enzyme catalyzes the hydrolysis of phosphomonoester bonds of a wide variety of molecules, especially polyphosphates. Thus, vacuolar polyphosphates are probably the natural substrate of this enzyme. Orthophosphate, arsenate, ethylenediaminetetraacetate, molybdate, and borate act as inhibitors. Fluoride is not an inhibitor, and the activity is not affected byp-hydroxymercuribenzoate. Some metal ions also affect the activity of vacuolar alkaline phosphatase. This may indicate that this enzyme is a metalloprotein.     

Structural insight into substrate binding and catalysis of a novel 2-keto-3-deoxy-D-arabinonate dehydratase illustrates common mechanistic features of the FAH superfamily

The archaeon Sulfolobus solfataricus converts d-arabinose to 2-oxoglutarate by an enzyme set consisting of two dehydrogenases and two dehydratases. The third step of the pathway is catalyzed by a novel 2-keto-3-deoxy-d-arabinonate dehydratase (KdaD). In this study, the crystal structure of the enzyme has been solved to 2.1 Å resolution. The enzyme forms an oval-shaped ring of four subunits, each consisting of an N-terminal domain with a four-stranded β-sheet flanked by two α-helices, and a C-terminal catalytic domain with a fumarylacetoacetate hydrolase (FAH) fold. Crystal structures of complexes of the enzyme with magnesium or calcium ions and either a substrate analog 2-oxobutyrate, or the aldehyde enzyme product 2,5-dioxopentanoate revealed that the divalent metal ion in the active site is coordinated octahedrally by three conserved carboxylate residues, a water molecule, and both the carboxylate and the oxo groups of the substrate molecule. An enzymatic mechanism for base-catalyzed dehydration is proposed on the basis of the binding mode of the substrate to the metal ion, which suggests that the enzyme enhances the acidity of the protons α to the carbonyl group, facilitating their abstraction by glutamate 114. A comprehensive structural comparison of members of the FAH superfamily is presented and their evolution is discussed, providing a basis for functional investigations of this largely unexplored protein superfamily.     

X-Ray Analysis of the Magnesium-containing Endonuclease from Serratia marcescens

The three-dimensional crystal structure of the DNA/RNA nonspecific endonuclease from Serratia marcescenswas refined at the resolution of 1.07 Å to Rfactor of 12.4% and R _freefactor of 15.3% using the anisotropic approximation. The structure includes 3924 non-hydrogen atoms, 715 protein-bound water molecules, and a Mg²⁺ion in each binding site of each subunit of the nuclease homodimeric globular molecule. The 3D topological model of the enzyme was revealed, the inner symmetry of the monomers in its N-and C-termini was found, and the local environment of the magnesium cofactor in the nuclease active site was defined. Mg²⁺ion was found to be bound to the Asn119 residue and surrounded by five associated water molecules that form an octahedral configuration. The coordination distances for the water molecules and the O¹atom of Asn119 were shown to be within the range of 2.01–2.11 Å. The thermal factors for the magnesium ion in subunits are 7.08 and 4.60 Ų, and the average thermal factors for the surrounding water molecules are 11.14 and 10.30 Ų, respectively. The region of the nuclease subunit interactions was localized, and the alternative side chain conformations were defined for 51 amino acid residues of the nuclease dimer.     

Crystal structure of a key enzyme in the agarolytic pathway, α-neoagarobiose hydrolase from Saccharophagus degradans 2-40

In agarolytic microorganisms, α-neoagarobiose hydrolase (NABH) is an essential enzyme to metabolize agar because it converts α-neoagarobiose (O-3,6-anhydro-alpha-l-galactopyranosyl-(1,3)-d-galactose) into fermentable monosaccharides (d-galactose and 3,6-anhydro-l-galactose) in the agarolytic pathway. NABH can be divided into two biological classes by its cellular location. Here, we describe a structure and function of cytosolic NABH from Saccharophagus degradans 2–40 in a native protein and d-galactose complex determined at 2.0 and 1.55 Å, respectively. The overall fold is organized in an N-terminal helical extension and a C-terminal five-bladed β-propeller catalytic domain. The structure of the enzyme–ligand (d-galactose) complex predicts a +1 subsite in the substrate binding pocket. The structural features may provide insights for the evolution and classification of NABH in agarolytic pathways.     

Structural basis for reduced activity of 1-aminocyclopropane-1-carboxylate synthase affected by a mutation linked to andromonoecy

1-aminocyclopropane-1-carboxylate synthase (ACS) is a key enzyme in the biosynthesis of the plant hormone ethylene. Recently, a new biological role for ACS has been found in Cucumis melo where a single point mutation (A57V) of one isoform of the enzyme, causing reduced activity, results in andromonoecious plants. We present here a straightforward structural basis for the reduced activity of the A57V mutant, based on our work on Malus domestica ACS, including a new structure of the unliganded apple enzyme at 1.35 Å resolution.     

Penicillium sp. 23 alpha-galactosidase: purification and substrate specificity

α-Galactosidase, a glycoprotein with carbohydrate and protein in ratio 1:6, has been isolated from liquid culture of micromycete Penicillium sp. 23 and purified to homogeneous state by ammonium sulphate precipitation followed by ion exchange and gel-filtration chromatography on TSK-gels. The Penicillium sp. 23 α-galactosidase specificity against a series of natural and synthetic substrates has been studied. The enzyme was found to exhibit strict specificity towards the glycon and hydrolyze exclusively α- -galactosides such as p-nitrophenyl-α- -galactopyranoside (p-NPhGal), melibiose, raffinose and stachyose. The configuration at C1 and C4 atoms of substrate as well as substitution at C2 and C6 of substrate made an important contribution to the interaction with the enzyme. The tested α-galactosidase exerted the highest affinity (K_m) with respect to the synthetic substrate p-NPhGal and maximal rate of hydrolysis (V_max), about 10 times higher, comparing with natural substrates (melibiose, raffinose and stachiose). The Penicillium sp. 23 α-galactosidase possesses wide specificity towards α-galactosidase hydrolysis link type, splitting off at varying rates the terminal galactose from disaccharides, attached by α-1,2-, α-1,3- and α-1,6-links. The enzyme is ineffective towards disaccharides with α-1,4-link. The enzyme showed potential to splitting off α-1,3-bound terminal galactose residues from antigens of the human blood group B(III) erythrocytes.